Nickel-Catalyzed Transfer Semihydrogenation and Hydroamination

Facultad de Química, Universidad Nacional Autónoma de México, Circuito Interior, Ciudad ... (1) Transfer hydrogenation has became an alternative to...
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Nickel-Catalyzed Transfer Semihydrogenation and Hydroamination of Aromatic Alkynes Using Amines As Hydrogen Donors Adan Reyes-Sanchez, Farrah Ca~navera-Buelvas, Rigoberto Barrios-Francisco, Olga L. Cifuentes-Vaca, Marcos Flores-Alamo, and Juventino J. García* Facultad de Química, Universidad Nacional Autonoma de Mexico, Circuito Interior, Ciudad Universitaria, Mexico City 04510, Mexico

bS Supporting Information ABSTRACT: The transfer hydrogenation of diphenylacetylene to yield cisand trans-stilbenes was achieved using a variety of amines as hydrogen donors and the complex 1 ([(dippe)Ni(μ-H)]2) in catalytic amounts (0.5% mol). The use of nucleophilic amines such as pyrrolidine in neat conditions afforded the hydroamination of diphenylacetylene, in moderate to high yields. Cyclization of 2-ethynylaniline also was carried out under similar conditions, with 1 in catalytic amounts, but in low yield, mainly due to the formation of homocoupling products of the starting material. The hydrogenation of diphenylacetylene by using other nitrogenated compounds such as aromatic N-heterocycles was addressed to give a metal-mediated process, using 1 in stoichiometric amounts.

1. INTRODUCTION Hydrogenation of alkynes to afford alkenes can be carried out by using hydrogen and a homogeneous or heterogeneous catalyst, such as the one developed by Lindar.1 Transfer hydrogenation has became an alternative to the use of dihydrogen on the small and middle scale, due to its simplicity and reduction of risks and operational difficulties associated with the use of gaseous hydrogen, along with the environmentally friendly properties of some hydrogen donors.2 Synthesis of alkenes through the semihydrogenation of alkynes is an important process since alkene derivatives are valuable building blocks for both academia and industry. In recent years, the research on homogeneous transfer semihydrogenation of alkynes has been focused on the use of complexes of noble metals such as iridium,3 ruthenium,4 and palladium,5 with methanol, 2-propanol, or the azeotropic mixture of HCOOH and NEt3 being the most common hydrogen sources. In this context, although the catalyzed dehydrogenation of amines is a well-known topic,6 their use in the reduction of alkynes has been scarcely studied,7 and one of the closest approaches to this process is the use of alkenes such as tert-butylethylene as hydrogen acceptors in the dehydrogenation of amines.6d Regarding the latter transformation, the hydrogen abstraction can be attained by the amino or aliphatic dehydrogenation8 depending on the substitution of the amine, resulting in the formation of imines or enamines as oxidation products, respectively. A further study on the hydrogen transfer from amines to alkynes would lead to a better understanding of their potential use as hydrogen donors as well as contribute to the implementation of synthetic methods for the synthesis of imines through the dehydrogenation of amines.9 On the other hand, a second pathway for the activation of alkynes is to achieve their hydroamination aimed to obtain imines, amines, and N-heterocycles.10 This has been a process r 2011 American Chemical Society

of interest due to the relative availability of the starting materials and the occurrence of derivatives of the synthesized compounds in many biological systems or their vast applications in pharmaceutical11 and agrochemical products.10a,12 Most of the developed work in the hydroamination of alkynes has largely been achieved by using palladium complexes,10b,13 even though there are many reports in which other metals such as titanium,10b,14 rare earth metals,15 and some late transition metals16 have been widely employed. However, despite the variety of developed organometallic catalysts, to date, few are examples of the use of complexes of nonexpensive metals such as nickel in the hydroamination of alkynes.16e,17 Herein we wish to report the semihydrogenation and hydroamination of diphenylacetylene and 2-ethynylaniline using complex 1 ([(dippe)Ni(μ-H)]2) along with amines and aromatic N-heterocyles as hydrogen sources. The relatively scarce use of amines as hydrogen sources as well as the nonexpensive metal based catalyst is spotlighted.

2. RESULTS AND DISCUSSION In order to assess the general reactivity of complex 1 toward the transfer hydrogenation and/or the hydroamination of diphenylacetylene (DPA), complex [(dippe)Ni(η2-C,C-DPA)] was synthesized according to the reported methodology18 using 1 and diphenylacetylene. Reaction of [(dippe)Ni(η2-C,C-DPA)] with 4 equiv of cyclohexylamine at 140 °C yielded the corresponding hydrogenation products. NMR spectra of the reaction mixture are evidence for the presence of complex [(dippe)Ni(η2C,C-trans-stilbene)]. Key signals for this complex were assigned in the 31P{1H} NMR at 66.94 ppm (s) and in the 1H NMR at Received: March 16, 2011 Published: June 03, 2011 3340

dx.doi.org/10.1021/om200233x | Organometallics 2011, 30, 3340–3345

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Scheme 1

Scheme 2

Table 1. Catalytic Hydrogenation of Diphenylacetylene Using Cyclohexylamine As Hydrogen Sourcea

entry

T (°C)

1 2

100 140

THF THF

400 400

3

180

THF

4

180

THF

5

180

6 7

solvent

1b (equiv)

yield (%)b

1c (%)

1d (%)

2 4

0 0

2 4

1000

15

5

10

2000

11

5

6

dioxane

2000

100

15

85

180

acetonitrile

2000

2

2

0

180

toluene

2000

69

10

59

a

All reactions were carried out in a stainless steel Parr reactor using 15 mL of solvent. A molar proportion of 1:200 of [(dippe)Ni(μ-H)]2 and diphenylacetylene, respectively, was employed. b Chromatographic yields.

Table 2. Catalytic Hydrogenation of Diphenylacetylene Using Pyrrolidine As Hydrogen Sourcea

4.49 ppm (s, br); also, based on the 1H NMR spectra, free cis(s, 6.40 ppm) and trans-stilbene (s, 6.95 ppm) were formed as represented in Scheme 1 (see Scheme 2 and Scheme S1, SI, for mechanistic proposals). After 77 h, the reaction was completed and the crude was analyzed by GC-MS. Chromatographic data showed complete hydrogenation of diphenylacetylene and the formation of cis- (17.5%) and trans-stilbene (82.5%) (Figure S3). To note, no hydroamination products were detected. Considering the above, experiments under catalytic conditions were assayed using a variety of solvents, temperatures, and proportions of cyclohexylamine, in order to find the optimized conditions for the hydrogenation of diphenylacetylene. The main results for these experiments are summarized in Table 1. According to these results, there is a low conversion when a coordinating solvent such as THF was used despite the increase in the quantity of the amine or temperature (entries 1 to 4). Catalytic conversion is enhanced when low coordinating solvents

entry

solvent

yield (%)b

1c (%)

1d (%)

2e (%)

1

THF

46

28

16

2

2

toluene

91

51

37

3

3

dioxane

100

26

71

3

4

neat

59

16

6

37

a

All reactions were carried out in a stainless steel Parr reactor using 15 mL of solvent. A molar proportion of 1:200:1000 of [(dippe)NiμH]2, diphenylacetylene, and amine, respectively, was used. b Chromatographic yields.

such as toluene or dioxane are used (entries 5 and 7). Imine 1e is a characteristic dehydrogenation transamination product from the transfer hydrogenation reaction,6a detected by GC-MS 3341

dx.doi.org/10.1021/om200233x |Organometallics 2011, 30, 3340–3345

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Table 3. Catalytic Hydrogenation of Diphenylacetylene Using Different Amines As Hydrogen Sourcesa,b,c,d

All reactions were carried out in a stainless steel Parr reactor using 15 mL of dioxane at 180 °C. A molar proportion of 1:200:1000 of [(dippe)Ni(μH)]2, diphenylacetylene, and amine, respectively, was used. ND = not determined. b Chromatographic yields. c Reaction at 160 °C. d 6.5 g of methylamine. One percent of the hydroamination product was also formed. a

(Figures S4 and S5, SI). When the reaction is carried out in acetonitrile (entry 6), the yield decreases dramatically probably due to the oxidative addition of this nitrile to nickel.19 As can be seen in Table 1 and also considering the results from the use of stoichiometric quantities of 1 (vide supra), the formation of trans-stilbene (thermodynamic product) suggests a Ni-catalyzed cis trans isomerization of the initially formed cis-stilbene (Scheme S1, SI).20 On using a different hydrogen donor, such as pyrrolidine (2b), rather similar results were obtained, as shown in Table 2. As seen before, a high conversion of diphenylacetylene to its corresponding hydrogenation products is attained by using low-coordinating solvents (toluene and dioxane), unlike the use of solvents such as THF. It is noticeable that in these experiments low amounts of the hydroamination product could be obtained (entries 1 to 3). Improved yields for the hydroamination process to produce 2e are obtained under neat conditions (entry 4, Table 2); this is a good result considering the low favored intermolecular hydroaminations.10 Clearly, the presence of these products shows the effect of the increase in the nucleophilicity of the hydrogen donor in the formation of condensation products.

The effect of structure and substitution of the hydrogen donor for different amines was also addressed using the conditions for 2b, summarized in Table 3. With the use of primary or secondary amines with R-H to the nitrogen atom, such as in 6b, the catalytic conversion can be successfully achieved as in the case of cyclohexylamine or pyrrolidine. For diamines 7b and 8b the conversion was decreased presumably because of the displacement of the substrate 1a from the metal center by the chelating diamines, resulting in the formation of [(dippe)Ni (diamino)] complexes, inhibiting the catalytic activity. Low to moderate yields are obtained on using aromatic N-heterocylces, such as 5b (entry 3), probably due to their low nucleophilicity. This effect also can be drastically noticed when protonated amines are used (entry 1). A mechanistic proposal for both catalytic hydroamination and transfer hydrogenation of alkynes is depicted in Scheme 2. A different set of hydrogen donors, such as tert-butylamine, indole, carbazole, and pyrrole, was tested. Nevertheless, none of these reagents afforded a catalytic reduction of 1a, and such transformation could be achieved only with the use of complex 1 in stoichiometric amounts. The lack of catalytic activity of these 3342

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the terminal alkyne (Figures S9 to S13, SI), along with hydroamination products between the produced indole and the starting material.

Figure 1. ORTEP drawing (50% probability) of [(dippe)Ni (k1C8H6N)2]. Selected bond lengths (Å) and angles (deg): N(1) Ni(1) 1.9307(16), N(2) Ni(1) 1.9339(15), P(1) Ni(1) 2.1836(5), P(2) Ni(1) 2.1834(5), N(1) Ni(1) N(2) 90.53(7), N(1) Ni(1) P(2) 176.59(5), N(2) Ni(1) P(2) 90.35(5), N(1) Ni(1) P(1) 91.76(5), N(2) Ni(1) P(1) 175.94(5), P(2) Ni(1) P(1) 87.55(2).

Table 4. Catalytic Cyclization of 2-Ethynilanilinea

yield (%)b

entry

solvent

1

dioxane

8

2

toluene

15

3

neat

25

a

All reactions were carried out in a stainless steel Parr reactor using 15 mL of dioxane, except for neat conditions, where 0.5 mL of 13b was used. A molar proportion of 1:200 of [Ni(dippe)μ-H]2 and 2-ethynilaniline was used. b Chromatographic yields.

systems is mainly due to the formation of rather stable N-coordinated complexes, like the one isolated when indole was employed as hydrogen source (Figure 1); here a Ni(II) complex in a square-planar geometry was observed. This complex was prepared independently in high yield reacting 1 with indole (see Experimental Section) and was highly thermally stable under argon. To further extend the reactivity found in the addition of amines to alkynes, the intramolecular cyclization of 2-ethynylaniline was explored in the conditions shown in Table 4. After 72 h, there was a complete conversion of the starting material; however, depending on the solvent, only 8% to 25% yield corresponds to the cyclization product and the remainder corresponds to other byproducts. GC-MS determinations are consistent with the formation of homocoupling products derived from the starting material via C H bond activation in

3. CONCLUSIONS We have shown a new methodology for the transfer hydrogenation of internal aromatic alkynes catalyzed by a nickel complex exhibiting moderate to excellent yields depending on the structure of the hydrogen donor. Transfer hydrogenation under the described conditions is sensitive to the use of coordinating solvents and hydrogen donors such as diamines, N-heterocycles, and THF due to the deactivation of the catalyst by those species linked to the formation of rather stable intermediates. Hydroamination is performed with better yields on using an excess of nucleophilic amine. The use of a substrate containing both a N H donor moiety and a terminal alkyne allowed cyclization, but there is a strong competence of C(sp) H bond activation by the metal center leading to homocoupled products. Studies are underway to decrease or avoid homocoupling. 4. EXPERIMENTAL SECTION Unless otherwise noted, all experiments were carried out using standard Schlenk techniques in a double vacuum-argon manifold or in a glovebox (MBraun Unilab) under high-purity argon (Praxair 99.998), with controlled concentrations of water and oxygen (